Practice Examinations Chem 393 Fall 2005 Time 1 hr 15 min for each set.

Similar documents
The Second Law of Thermodynamics (Chapter 4)

MME 2010 METALLURGICAL THERMODYNAMICS II. Fundamentals of Thermodynamics for Systems of Constant Composition

Identify the intensive quantities from the following: (a) enthalpy (b) volume (c) refractive index (d) none of these

Module 5 : Electrochemistry Lecture 21 : Review Of Thermodynamics

Chpt 19: Chemical. Thermodynamics. Thermodynamics

CHAPTER THERMODYNAMICS

UNIT 15: THERMODYNAMICS

CHEM Exam 2 - October 11, INFORMATION PAGE (Use for reference and for scratch paper)

Lecture 3 Evaluation of Entropy

OCN 623: Thermodynamic Laws & Gibbs Free Energy. or how to predict chemical reactions without doing experiments

Thermodynamic Third class Dr. Arkan J. Hadi

Chapter 7. Entropy. by Asst.Prof. Dr.Woranee Paengjuntuek and Asst. Prof. Dr.Worarattana Pattaraprakorn

CHEMICAL THERMODYNAMICS

The Gibbs Phase Rule F = 2 + C - P

Physical Biochemistry. Kwan Hee Lee, Ph.D. Handong Global University

For more info visit

CHEMISTRY 202 Hour Exam II. Dr. D. DeCoste T.A (60 pts.) 31 (20 pts.) 32 (40 pts.)

Chapter 5. Simple Mixtures Fall Semester Physical Chemistry 1 (CHM2201)

Chapter 19 The First Law of Thermodynamics

I. Multiple Choice Questions (Type-I)

MS212 Thermodynamics of Materials ( 소재열역학의이해 ) Lecture Note: Chapter 7

Chapter 19 Chemical Thermodynamics Entropy and free energy

Chapter 19 Chemical Thermodynamics Entropy and free energy

First Law of Thermodynamics Basic Concepts

CHEMISTRY 202 Practice Hour Exam II. Dr. D. DeCoste T.A (60 pts.) 21 (40 pts.) 22 (20 pts.)

Thermodynamics Free E and Phase D. J.D. Price

Chapter 3. The Second Law Fall Semester Physical Chemistry 1 (CHM2201)

Spontaneous Change.! Although exothermic processes tend to be spontaneous, spontaneous reactions can be exothermic or endothermic:

1 mol ideal gas, PV=RT, show the entropy can be written as! S = C v. lnt + RlnV + cons tant

Concentrating on the system

UNIVERSITY COLLEGE LONDON. University of London EXAMINATION FOR INTERNAL STUDENTS. For The Following Qualifications:-

Name: Discussion Section:

UNIVERSITY OF SOUTHAMPTON

Chapter 7. Entropy: A Measure of Disorder

Temperature Thermal Expansion Ideal Gas Law Kinetic Theory Heat Heat Transfer Phase Changes Specific Heat Calorimetry Heat Engines

Entropy & the Second Law of Thermodynamics

Thermodynamic Processes and Thermochemistry

Last Name or Student ID

Lecture. Polymer Thermodynamics 0331 L First and Second Law of Thermodynamics

Exam 4, Enthalpy and Gases

Summarizing, Key Point: An irreversible process is either spontaneous (ΔS universe > 0) or does not occur (ΔS universe < 0)

Chapter 8 Thermochemistry: Chemical Energy

Chapter 16: Spontaneity, Entropy, and Free Energy Spontaneous Processes and Entropy

Chem Lecture Notes 6 Fall 2013 Second law

Outline of the Course

UNIVERSITY OF SOUTHAMPTON

Physics is time symmetric Nature is not

General Physical Chemistry I

S = k log W CHEM Thermodynamics. Change in Entropy, S. Entropy, S. Entropy, S S = S 2 -S 1. Entropy is the measure of dispersal.

This follows from the Clausius inequality as a consequence of the second law of thermodynamics. Therefore. (for reversible process only) (22.

Hence. The second law describes the direction of energy transfer in spontaneous processes

Chap. 3. The Second Law. Law of Spontaneity, world gets more random

Version 001 HW 15 Thermodynamics C&J sizemore (21301jtsizemore) 1

4/19/2016. Chapter 17 Free Energy and Thermodynamics. First Law of Thermodynamics. First Law of Thermodynamics. The Energy Tax.

THERMODYNAMICS. Extensive properties Intensive properties

Engineering Thermodynamics. Chapter 6. Entropy: a measure of Disorder 6.1 Introduction

I PUC CHEMISTRY CHAPTER - 06 Thermodynamics

Thermodynamics of solids 5. Unary systems. Kwangheon Park Kyung Hee University Department of Nuclear Engineering

PY Introduction to thermodynamics and statistical physics Summer Examination suggested solutions Dr. Asaf Pe er

Thermodynamics. Chem 36 Spring The study of energy changes which accompany physical and chemical processes

Name: Discussion Section:

AAE COMBUSTION AND THERMOCHEMISTRY

S = k log W 11/8/2016 CHEM Thermodynamics. Change in Entropy, S. Entropy, S. Entropy, S S = S 2 -S 1. Entropy is the measure of dispersal.

Chapter 3. Property Relations The essence of macroscopic thermodynamics Dependence of U, H, S, G, and F on T, P, V, etc.

University of Washington Department of Chemistry Chemistry 452/456 Summer Quarter 2011

THERMODYNAMICS I. TERMS AND DEFINITIONS A. Review of Definitions 1. Thermodynamics = Study of the exchange of heat, energy and work between a system

Physics 119A Final Examination

Entropy, Free Energy, and Equilibrium

Outline of the Course


Enthalpy and Adiabatic Changes

Chemical thermodynamics the area of chemistry that deals with energy relationships

Ch. 6 Enthalpy Changes

열과유체, 에너지와친해지기 KAIST 기계공학과정상권

Atkins / Paula Physical Chemistry, 8th Edition. Chapter 3. The Second Law

Equations: q trans = 2 mkt h 2. , Q = q N, Q = qn N! , < P > = kt P = , C v = < E > V 2. e 1 e h /kt vib = h k = h k, rot = h2.

THERMODYNAMICS. Topic: 4 Spontaneous processes and criteria for spontaneity, entropy as a state function. VERY SHORT ANSWER QUESTIONS

CHAPTER 3 LECTURE NOTES 3.1. The Carnot Cycle Consider the following reversible cyclic process involving one mole of an ideal gas:

Thermodynamic Laws, Gibbs Free Energy & pe/ph

N h (6.02x10 )(6.63x10 )

Chapter 17. Free Energy and Thermodynamics. Chapter 17 Lecture Lecture Presentation. Sherril Soman Grand Valley State University

where R = universal gas constant R = PV/nT R = atm L mol R = atm dm 3 mol 1 K 1 R = J mol 1 K 1 (SI unit)

Chapter 11 Spontaneous Change and Equilibrium

Problem: Calculate the entropy change that results from mixing 54.0 g of water at 280 K with 27.0 g of water at 360 K in a vessel whose walls are

Thermodynamics C Test

The Chemical Potential

I affirm that I have never given nor received aid on this examination. I understand that cheating in the exam will result in a grade F for the class.

Lecture 3 Clausius Inequality

A) 2.0 atm B) 2.2 atm C) 2.4 atm D) 2.9 atm E) 3.3 atm

II/IV B.Tech (Regular) DEGREE EXAMINATION. (1X12 = 12 Marks) Answer ONE question from each unit.

Downloaded from

Physical Chemistry I Exam points

1. (10) True or False: A material with an ideal thermal equation of state must have a constant c v.

I. The Nature of Energy A. Energy

Outline Review Example Problem 1. Thermodynamics. Review and Example Problems: Part-2. X Bai. SDSMT, Physics. Fall 2014

Thermodynamics of Reactive Systems The Equilibrium Constant

Physics 5D PRACTICE FINAL EXAM Fall 2013

Thermodynamics II. Week 9

Chapter 19 Chemical Thermodynamics

CHEMICAL THERMODYNAMICS. Nature of Energy. ΔE = q + w. w = PΔV

Transcription:

Practice Examinations Chem 393 Fall 2005 Time 1 hr 15 min for each set. The symbols used here are as discussed in the class. Use scratch paper as needed. Do not give more than one answer for any question. It will automatically disqualify both answers. [R = 8.315 J/Kmol; 1 atm = 101.3kPa] Name:

Exam I 1. Derive the thermometric equation for the centigrade scale, in terms of gas pressure. 4. What is the heat produced when a gas is compressed, under isothermal conditions, from its initial state p1, V1, T1 to a final state, p2, V2, T1? Consider it to be one-step compression by an external pressure, which is twice the final pressure. 2. Show that the pressure exerted by a liquid column is a product of its density, height of the column and acceleration due to gravity? 5. Indicate if the following statements are true or false: 3. If a gas has a density ρ at pressure p, what is its root mean square velocity in terms of density and pressure? a. Melting of ice at zero degrees centigrade, 1 atm (in equilibrium with liquid water) is a reversible process. [ ] b. Energy is neither created nor destroyed. [ ] c. The coefficient of volume expansion for a gas is negative. [ ] d. Perpetual motion machine of the second kind is possible.

6. Show that p = ρ RT/M, starting from the ideal gas law. 9. Plot p versus V, for an isothermal, reversible expansion of an ideal gas. 7. Use the expression for pv = (1/3) Nm<c 2 > (kinetic theory of gases) and show that the internal energy of the gas is (3/2) nrt. 10. Plot pressure versus height, at constant T, for oxygen and nitrogen gases. 8. Derive an expression for the work done during single step isothermal, reversible expansion of an ideal gas.

11. Starting from the second law of thermodynamics, show that S = Cp ln(t2/t1) for an ideal gas, at constant pressure. 13. Plot S vs T for Carnot cycle (4 step, reversible cycle)? 14. Plot entropy vs pressure of an ideal gas. 12. Show that the work done in an adiabatic expansion of an ideal gas is equal to change in its internal energy. 15. Plot H vs T for the Carnot cycle.?

Practice Exam II: 1. Show that TdS = du + pdv, starting from the first and the second laws? 3. What is the entropy change when 1 mol of ice melts to water at 0 C, and 1 atm? Heat of fusion of water is 22 J/Kmol. 2. What is the entropy change due to isothermal expansion of 1 mol of an ideal gas such that the volume doubles. 4. What is the number of possible distinguishable arrangements of five identical objects in seven boxes (single occupancy in each box)?

5. If change in the internal energy when one mol of hydrogen reacts with half a mol of oxygen is 250 kcal, at 300 K, what is the corresponding enthalpy change? 7. One mol of a gas is heated at constant volume from 300K to 500K. If Cv for one mol of the gas is (3/2)R, calculate the entropy change for this process. 9. Show that TdS = du + pdv (constant pressure, pv work only) 6. Cp of solid silver is 23.43 + 0.00628T in units of J/Kmol. Calculate H when 3 mol of silver is heated from 25 C to its melting point, 961 C, at 1 atm. 10. Show that ds> dqirr/t for all irreversible processes (Clausius inequality)

11. Show that q for a constant volume process is a state function. 14. A. The entropy change accompanying an isothermal expansion of 1 mol of ideal gas when the volume doubles is a. Rln2 b. 1/12 x R c. -ln2 d. Rln1/2 e.none of these B. The efficiency of a cyclic engine operating between 200 K and 300 K is a. 0.277 b. -0.3 c. 1/3 d. -1/3 e. 1/2 C. The efficiencies of a steam engine (high t = 100 C) in summer time (when the lower t is at 20 C) and in winter time (when the lower T is at -20 C) are a. 0.5 and 0.4 b. 0.33 and 0.67 c. 0.41 and 0.54 d. 0.22 and 0.32 D. The entropy change when 1 mol of ice melts to water at 273 K, 1 atm is 22 J K -1 mol -1. The molar enthalpy change of water is a. 22 x 273 J/mol b. -22 x 273 J/mol c. 22/273 J/mol d.-22/273 J/mol. 12. Graph S vs p for an ideal gas, constant T. 15. Plot G mixing as a function of mole fraction of a component in a binary mixture. 13. Plot entropy vs p for an adiabatic reversible expansion.

Practice Exam III (some questions are bit more advanced) 1. Draw the phase diagram of any substance other than water at the region of the triple point. 4. Show that d(g/t)/dt = - H/T 2 at constant pressure. 2. Plot chemical potential of a solid phase as a function of temperature. 5. Show that: dh = TdS + Vdp 3. Show that dg=vdp - SdT.?

8. What is the change in temperature in the above process? 6. Show µ = µ + RT ln p. 7. Calculate the change in volume when 1 mol of hydrogen at 1 atm and 25 C is mixed with 2 mol of nitrogen at 1 atm and 25 C. Assume ideal mixture. 9. What is G when 2 mol of hydrogen is mixed with 1 mol of carbon dioxide at 300 K? Chemical potentials of these substances are 2 and 3 kj/mol, respectively, at 300 K. 10. What is A when 1 mol of hydrogen reacts with 2 mol of oxygen, if the reaction is carried out at constant temperature and constant volume?

13. Show that the work done in an isothermal reversible expansion of an ideal gas is - p 2 V 2 ln(v 2 /V 1 ). 11. Indicate if the following statements are true or false a. Gibbs free energy increases during any chemical reaction. b. Entropy of the universe is increasing with time. 14. Show that work done in an irreversible cyclic transformation is >0. c. All exothermic reactions are spontaneous processes. d. Free energy decreases during any spontaneous process. e. For an ideal mixture, the Gibbs free energy of mixing is zero. f. The Gibbs free energy of an ideal gas decreases with increase in pressure. 12. Show that w is a path function. 15. Derive an expression for the work done by an ideal gas during a reversible isothermal expansion.

3. Plot enthalpy vs p for an isothermal reversible expansion for an ideal gas. Some additional questions: 1. Derive an expression for the work done by an ideal gas due to an isothermal irreversible expansion against an opposing pressure. 4. A. S when 24 mg of N2 at 89 torr and 22 C expands adiabatically into vacuum to a final pressure of 34 torr, S is (assume perfect gas behavior). a. 8.7 J/K b. 27 mj/k c. 1.2 J/K d. 6.9 mj/k B. S for the melting of 5.0 g of ice (fusion enthalpy is 79.7 cal/g) at 0 C and 1 atm is a. 2.56 cal/k b. 1.2 cal/k c. 1.46 cal/k d. 6.17 J/K C. The entropy change when an ideal gas (1 mol) undergoes free expansion (into vaccum) at 300 K is a. >0 b. <0 c. =0 d. e. None of these D. Melting of a solid in equilibrium with its liquid is a reversible process a. false b. true c. may be d. none of these More Questions 2. Show that the magnitude of work done in a two step isothermal expansion is more than a single step isothermal expansion (same initial and final states). 1. Graph S vs T for an ideal gas, constant V. 2. Plot entropy vs volume, ideal gas at constant T. 3. Graph S vs U for an ideal gas, constant V. 4. Plot p vs V for Carnot cycle. 5. Plot ε vs 1/T 2 for the above cycle. 6. Plot H vs T for the above cycle. 7. Graph U vs T for a reversible cycle consisting of two expansion and two compression steps (Carnot Cycle). 8. Plot p vs V for the above cycle. 9. What will be W cycle if the two temperatures of the above cycle are equal? 10. Graph q p vs T at constant pressure for an ideal gas. 11. Graph Cp vs T for an ideal gas. 12. Graph T vs p for an isoenthalpic/adiabatic expansion of an ideal gas.

13. Graph work done in an isothermal reversible expansion as a function of temperature for an ideal gas. 14. Graph the same as above but for an irreversible expansion. 15. Graph q vs T for an ideal gas at constant volume (Cv is a constant). 16. Graph work done in an isothermal reversible expansion as a function of increasing initial pressure for an ideal gas. 17. Show that du = C v dt for an ideal gas. 18. Graph U vs T for an ideal gas, constant V. Indicate Cv. 19. Graph q vs T for the heating of ice from 263 K to 283 K at atm. pressure (assume Cp of water and Cp of ice are constants). 20. Graph work done during one-step isothermal compressiondue to an external pressure of p ext. 21. Graph work done during isothermal reversible expansion of an ideal gas. 22. Graph the work done in two-step isothermal expansion of a gas. 23. A. The work done during the one-step isothermal expansion of a gas against constant external pressure (P ex ) is a. P ex xchange in Volume b. - P ex xchange in Volume c.0 d. unknown B. The magnitude of work done during a reversible isothermal expansion of an ideal gas (W rev ) is related to the corresponding work done during an irreversible expansion (W irr ) as a. W rev < W irr b. W rev = W irr c. W rev > W irr d. W irr =0 C. The work done by an ideal gas (1mol) during an isothermal expansion into vacuum with a change in volume equal to 25 lit. at 300 K is a. 25 lit atm b. >25 lit atm c. 0 d. <0 e. None of these D. Total entropy change S (system + surroundings) when an irreversible change occurs in the system is a. <0 b. >0 c. = 0 d. None of these e. 0.5R

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback